材料科学
插层(化学)
双功能
纳米技术
电池(电)
阴极
硫化物
储能
原位
电极
表征(材料科学)
锂(药物)
机制(生物学)
纳米颗粒
相(物质)
纳米尺度
吸附
原子单位
分层(地质)
硫化铜
石墨烯
混合材料
能量转换
纳米结构
密度泛函理论
化学工程
作者
Jianxin Tian,Yuan Li,Xu-Sheng Zhang,Zhen-Zhen Shen,Rui-Zhi Liu,Shuang-Yan Lang,Yu‐Guo Guo,Rui Wen
标识
DOI:10.1002/adma.202522007
摘要
ABSTRACT Conventional cathodes of lithium battery relying on single storage mechanisms—whether intercalation or conversion—face intrinsic limitations in energy density and sluggish electrode kinetics. Hybrid systems combining both mechanisms offer promising pathways to transcend these constraints; yet, their dynamic interfacial synergies remain poorly deciphered at the nanoscale. This study employs multimodal in situ characterization (Electrochemical atomic force microscopy/Raman/Electrochemical impedance spectroscopy) to elucidate the dynamic synergy in TiS 2 ‐S hybrid cathodes, revealing the concurrent interfacial evolution during cycling: nanoscale steps formation via Li‐ion intercalation in the TiS 2 ‐LiTiS 2 host and the phase transformation of S‐Li 2 S/Li 2 S 2 . Crucially, the TiS 2 /LiTiS 2 serves as a bifunctional interface that not only contributes capacity but also mediates sulfide adsorption and catalyzes preferential edge‐directed sulfide deposition. The partially delithiated Li x TiS 2 enhances electronic conductivity, creating rapid electron transport that facilitates subsequent interfacial sulfide conversion reaction. The hybrid storage mechanism retains features characteristic of both S and TiS 2 storage mechanisms, yet manifests synergistic interfacial reconstruction rather than simple superposition, achieving enhanced reversibility, exceptional cycling stability, and superior rate capability.
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